JPH0373882A - Instrument for measuring radiant ray - Google Patents

Abstract

PURPOSE:To expand a dynamic range by adding analog switch, a voltage compa rator, etc., to a photon counting method circuit system. CONSTITUTION:When incident dosage is high, the output of an I-V converter 2 exceeds a reference voltage V2 with the lapse of time, the output of a voltage comparator 5b is turned to 'L', the analog switch 4 is closed, the accumulated charge of a feedback capacitor C2 is instantaneously discharged, the output of the converter 2 is turned to the '0' level again, the output of the comparator 5b is turned to the 'H' level, the switch 4 is opened, and then the output of the converter 2 is increased again. The process is successively repeated, the 'L' level frequency of the output of the comparator 5b, i.e. the closed frequency of the switch 4, is counted by a counter 6b and the count value and a count value based upon the pulse counting method of a counter 6a are inputted to a data processor 7. Measurement information correlated with the number of practical incident photon is obtained by correcting the pulse counting miss in the count values of the counter 6a by the processor 7 based upon an integra tion value outputted from the converter 2. Consequently, the dynamic range can be expanded.

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to a radiation detection device that can be used in various fields such as medical X-ray imaging devices and industrial non-destructive testing devices.

<Prior art> Radiation measurement methods include the photon counting method, which measures incident radiation by counting pulse signals output by radiation incident on a radiation detector, and the photon counting method, which measures the incident radiation by integrating the output of the radiation detector. There are integral methods for measuring incident radiation.

By the way, according to the photon counting method, when the amount of incident radiation is low, radiation can be measured accurately, but when the amount of incident radiation is high, the output pulses of the radiation detector cause pile-up, resulting in pulses being omitted. There is a problem that occurs.

On the other hand, according to the integral method, since the output of the radiation detector is integrated, it is possible to measure even if pile-up occurs.
Compared to the photon counting method, this method has the problem that errors caused by fluctuations in the offset output of the detector, etc., have a large effect on the measured values, making it unsuitable for low-dose radiation measurements.

Therefore, conventionally, a circuit system for the photon counting method was included in one device.
and an integral method circuit system, and depending on the incident radiation dose,
We are building a radiation measurement device with a wide dynamic range that allows you to select either one of the circuit systems.

<Problem to be solved by the invention> By the way, in the above-mentioned device, the circuit system based on the integral method is
The output of the radiation detector is integrated by an integrator, the output of the integrator is latched, and then converted to a digital signal by an A/D converter, which makes the circuit system complicated and large-scale. However, extra time is required for A/D conversion, resulting in a problem of slow response.

An object of the present invention is to provide a radiation measuring device that can measure radiation over a wide range from low doses to high doses without using an integrator, an A/D converter, or the like.

Means for Solving the Problems> A configuration for achieving the above object will be described with reference to FIG. 1 corresponding to an embodiment. 1, an I-■ converter 2 that inputs the current pulse, and a pulse counter (first
In a device equipped with a counter) 6a, which is connected in parallel between the input and output of the I-V converter 2, when the output of the 1-V converter 2 exceeds a preset reference value v2, "
Based on the outputs of the analog switch 4 which becomes "closed", the counting means (second counter) 6b that counts the number of times the analog switch becomes "closed", and the respective outputs of the counting means 6b and the pulse counter 6a. , is characterized by the provision of data processing means 7 that outputs measurement information of the incident radiation dose.

Effect〉 If the reference value ■2 is set to a value higher than the output peak value of the I-V converter 2 when one radiation photon is incident on the radiation detector 1, the incident radiation dose will be lower. , when no pile-up has occurred, the analog switch 4 is
The "open" state is held and the incident radiation dose is counted by conventional photon counting methods.

On the other hand, when the incident radiation dose is high, as shown in FIG. 2, a pile-up occurs in the output of the IV converter 2, and the output increases with time and exceeds the reference value Vz. At this time, the analog switch 4 becomes "closed" after a predetermined period of time has elapsed since the output of the I-V converter 2 exceeded the reference value v2, and from the time when the output of the I-V converter 2 returned to zero level. After a predetermined time has elapsed, the analog switch 4 becomes "open" and this operation is repeated one after another, and the number of times the analog switch 4 becomes "closed" is counted by the counting means 6b at the subsequent stage.

Here, when a pile-up occurs, the count value recorded in the pulse counter 6a of the circuit system using the photon counting method is a lower value than the true count value due to the pulse count being omitted. This pulse counter 6a and counting means 6
In the data processing means 7, each count value of b is
For example, if a predetermined weighting is performed and then the two are added, the output of the data processing means 7 becomes information that approximates the true count value, with the pulse counts corrected.

<Embodiment> FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention.

A current pulse signal outputted by radiation incident on the semiconductor radiation detector 1 is guided to the ■-■ converter 2, charged in its feedback capacitance Cz, and converted into a voltage signal. After this voltage pulse signal is amplified by the voltage amplifier 3 via the capacitor C5, only the pulse signals having a predetermined peak value (1) or more are extracted by the first voltage comparator 5a. Then, the effective pulse discriminated by the voltage comparator 5a is
It is counted by a first binary counter 6a.

The above circuit system is similar to a circuit system based on a known photon counting method. Note that the output signal of the I-V converter 2 is amplified by the voltage amplifier 3, and at the same time, noise components are removed by the capacitor C5 and the amplifier 3, and the output signal is sent to the next stage voltage comparator 5.
guided by a.

Now, an analog switch 4 is connected in parallel between the input and output of the IV converter 2. This analog switch 4 is a switch that is driven to open and close according to the output of the second voltage comparator 5b, and is "open" when the output of the voltage comparator 5b is "H" level, and "closed" when the output is "L" level. Become.

The second voltage comparator 5b inputs the output signal of the IV converter 2, and when the input signal is lower than the reference voltage V2,
It outputs an H level signal, and when it is above, it outputs an "L" level signal. Its output is the second binary counter 6
b. The binary counter 6b counts the number of times the output of the voltage comparator 5b becomes "L" level, that is, the number of times the analog switch 4 becomes "closed". Here, the reference voltage V2 of the voltage comparator 5b is the voltage applied to the I-V converter 2 when one radiation photon is incident on the radiation detector 1.
is set to a value higher than the output peak value of.

The above outputs of the first and second counters 6a and 6b are led to the data processing device 7. The data processing device 7 weights each of the derived two count values with a predetermined value, and then adds them together. That is, for example, the third
As shown in the figure (a), by correcting the pulse count of the first counter 6a for the incident photons by the count value of the second counter 6b, the incident photon as shown in the figure (b) is corrected. It is configured to output information proportional to photons.

FIG. 2 is a waveform diagram showing the operation of the embodiment of the present invention.

First, when the incident radiation dose is low and no pile-up occurs, the output of the IV converter 2 never exceeds the reference voltage v2 of the second voltage comparator 5b, and the analog switch 4 is always "open". '' is maintained, and nothing is recorded in the second counter 6b. Therefore, the data processing device 7
Only the counted value recorded by the first counter 6a, that is, the counted value by the conventional pulse counting method, is input to the data processing device 7, and information corresponding to the counted value is outputted from the data processing device 7.

Now, when the incident radiation dose is high, as shown in FIG. 2, a pile-up occurs in the output of the IV converter 2, and the output increases over time to exceed the reference voltage V2. When the output of the IV converter 2 exceeds the reference voltage V2, the output of the second voltage comparator 5b becomes rl, J level, and then the analog switch 4 closes. By closing the analog switch 4, the I-V
The charge accumulated in the feedback capacitor itc of the converter 2 is instantly discharged, and the output of the IV converter 2 returns to the zero level again. As a result, the output of the second voltage comparator 5b becomes “H”.
” level, the analog switch 4 becomes “open” and the output of the IV converter 2 increases again. The above operations are repeated in sequence, and the output of the second voltage comparator 5b becomes "L".
The number of times the analog switch 4 reaches the level, that is, the number of times the analog switch 4 is "closed" is counted by the second counter 6b at the subsequent stage, and the counted value and the counted value by the first counter 6a are input to the data processing device 7. be done.

Note that the delay in the output of the second voltage comparator 5b and the opening/closing operation of the analog switch 4 is due to the operating time characteristics of each functional component.

Here, when the incident radiation dose is high, the counted value by the first counter 6a is lower than the actual number of incident photons due to pulse counting, but the data processing device By performing correction based on the count value of the second counter 6b, that is, the output integral value of the IV converter 2, measurement information correlated to the actual number of incident photons can be obtained.

In addition, in the above embodiment of the present invention, the I-■ converter 2
All the circuits from 1 to 6a and 6b can be integrated into one chip using an integrated circuit manufacturing process.

<Effects of the Invention> As explained above, according to the present invention, the integrator and the
A radiation measuring device with a wide dynamic range can be constructed by simply adding an analog switch, a voltage comparator, etc. to the circuit system of the conventional photon counting method, without using a /D converter or the like. Moreover, the measurement circuit system is simple, and
Since it can be integrated into an IC, the device can be made smaller and simpler. Also, since no time is required for A/D conversion, radiation measurements can be obtained faster than with conventional devices. Furthermore, since analog switches and voltage comparators operate with a lower power supply voltage than A/D converters and the like, there is also the effect that power consumption can be reduced.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention. FIG. 2 is a waveform chart showing the operation of the embodiment of the present invention. FIG. 3 is a diagram for explaining the functions of the data processing device according to the embodiment of the present invention. 1... Semiconductor radiation detector 2... I-V converter 3... Voltage amplifier 4... Analog switch 5a... First voltage comparator 5b... Second voltage comparator 6a ...First binary counter 6b...Second binary counter data processing device

Claims (1)

[Claims] A radiation detector that generates current pulses by radiation incidence, an IV converter that inputs the current pulses, and this I-V converter that inputs the current pulses.
- A device equipped with a pulse counter that inputs the output pulse signal of the V converter, which is connected in parallel between the input and output of the above-mentioned I-V converter, and the output of the I-V converter is set to a preset reference value. An analog switch that closes when the amount 1. A radiation measurement device, characterized in that it is provided with a data processing means for outputting measurement information.